How much Replacement does this axiom provide?When does collection imply replacement?Finite order arithmetic and ETCSHow would set theory research be affected by using ETCS instead of ZFC?Small Implications of the Axiom of ReplacementPFA: A New Godel's Program & A New Large Cardinal Ladder (Updated)Have axioms / axiom schemata of this flavour been proposed or otherwise considered?Who needs Replacement anyway?Existence of regular cardinals larger than an arbitrary cardinal in von Neumann universes without axiom of choiceIs this schema equivalent to Replacement under removal of Extensionality?Is restricting Replacement and Separation enough to make $Q+ISigma_n$ bi-interpretable with Set Theory?
How much Replacement does this axiom provide?
When does collection imply replacement?Finite order arithmetic and ETCSHow would set theory research be affected by using ETCS instead of ZFC?Small Implications of the Axiom of ReplacementPFA: A New Godel's Program & A New Large Cardinal Ladder (Updated)Have axioms / axiom schemata of this flavour been proposed or otherwise considered?Who needs Replacement anyway?Existence of regular cardinals larger than an arbitrary cardinal in von Neumann universes without axiom of choiceIs this schema equivalent to Replacement under removal of Extensionality?Is restricting Replacement and Separation enough to make $Q+ISigma_n$ bi-interpretable with Set Theory?
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(There have been many questions on MathOverflow about the axiom scheme of replacement, including a few with a similar flavour to mine. Some have very informative answers and link to excellent papers and blog posts. I've spent a while reading the older questions etc., and as far as I know, my question isn't answered in any of them — but it's entirely possible that it is and I missed it. In that case, I'll be grateful if someone points out where.)
Consider the following statement about sets and functions, which I'll call "axiom A":
A. For all well-ordered sets $(B, leq)$, there exist a set $X$ and a function $p: X to B$ with the following property:
for all $b in B$, the fibre $p^-1(b)$ is an infinite set of smallest cardinality greater than that of $p^-1(b')$ for each $b' < b$.
In the traditional notation of set theory, if $(B, leq)$ is an ordinal $beta$, then $p^-1(alpha) cong aleph_alpha$ for each $alpha in beta$. So, $X$ is the disjoint union $coprod_alpha in beta aleph_alpha$ and $p: X to beta$ is the obvious projection.
My question is about ETCS (Lawvere's Elementary Theory of the Category of Sets) together with axiom A. In what follows, I'm going to take ETCS as the background theory. Thus, when I say "this is weaker than that", I mean weaker in the presence of ETCS.
On the one hand, A isn't a theorem of ETCS (unless, of course, ETCS is inconsistent). That's because ETCS+A proves the existence of $aleph_omega$ but ETCS alone doesn't.
On the other, if I'm not mistaken, A is weaker than replacement. That's because ETCS+replacement is bi-interpretable with ZFC, and unless I'm misremembering, the fact that ETCS+A is a finite list of axioms (not involving axiom schemes) somehow implies that it can't be as strong as ZFC.
So, it seems that axiom A is a weaker form of replacement. My question:
To what fragment of replacement is axiom A equivalent (in the presence of the axioms of ETCS)?
That question is a little vague, so let me focus it more:
What's the simplest statement you can think of that's true in ETCS+replacement (or equivalently ZFC) but not provable in ETCS+A?
I don't mind whether the statement is purely set-theoretic or from another part of mathematics.
ct.category-theory set-theory lo.logic
$endgroup$
add a comment |
$begingroup$
(There have been many questions on MathOverflow about the axiom scheme of replacement, including a few with a similar flavour to mine. Some have very informative answers and link to excellent papers and blog posts. I've spent a while reading the older questions etc., and as far as I know, my question isn't answered in any of them — but it's entirely possible that it is and I missed it. In that case, I'll be grateful if someone points out where.)
Consider the following statement about sets and functions, which I'll call "axiom A":
A. For all well-ordered sets $(B, leq)$, there exist a set $X$ and a function $p: X to B$ with the following property:
for all $b in B$, the fibre $p^-1(b)$ is an infinite set of smallest cardinality greater than that of $p^-1(b')$ for each $b' < b$.
In the traditional notation of set theory, if $(B, leq)$ is an ordinal $beta$, then $p^-1(alpha) cong aleph_alpha$ for each $alpha in beta$. So, $X$ is the disjoint union $coprod_alpha in beta aleph_alpha$ and $p: X to beta$ is the obvious projection.
My question is about ETCS (Lawvere's Elementary Theory of the Category of Sets) together with axiom A. In what follows, I'm going to take ETCS as the background theory. Thus, when I say "this is weaker than that", I mean weaker in the presence of ETCS.
On the one hand, A isn't a theorem of ETCS (unless, of course, ETCS is inconsistent). That's because ETCS+A proves the existence of $aleph_omega$ but ETCS alone doesn't.
On the other, if I'm not mistaken, A is weaker than replacement. That's because ETCS+replacement is bi-interpretable with ZFC, and unless I'm misremembering, the fact that ETCS+A is a finite list of axioms (not involving axiom schemes) somehow implies that it can't be as strong as ZFC.
So, it seems that axiom A is a weaker form of replacement. My question:
To what fragment of replacement is axiom A equivalent (in the presence of the axioms of ETCS)?
That question is a little vague, so let me focus it more:
What's the simplest statement you can think of that's true in ETCS+replacement (or equivalently ZFC) but not provable in ETCS+A?
I don't mind whether the statement is purely set-theoretic or from another part of mathematics.
ct.category-theory set-theory lo.logic
$endgroup$
2
$begingroup$
One easy way to see that this is weaker than Replacement is to take any $beth$-fixed point, $delta$, and look at $V_delta$ as a model of Zermelo set theory (which is stronger than ETCS) where $aleph_alpha$ exists for every ordinal $alpha$, and every well-ordered set is isomorphic to a von Neumann ordinal. So the question is, essentially, how much Replacement holds for the least such $delta$...
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
Also, note that Power set is quite essentially here. Otherwise $H(omega_1)$, the set of hereditarily countable sets, satisfies ZFC-Power set (including full Replacement), but all infinite sets are equipotent there.
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
@AsafKaragila yes, a topos has power objects, so we are ok there :-)
$endgroup$
– David Roberts
1 hour ago
add a comment |
$begingroup$
(There have been many questions on MathOverflow about the axiom scheme of replacement, including a few with a similar flavour to mine. Some have very informative answers and link to excellent papers and blog posts. I've spent a while reading the older questions etc., and as far as I know, my question isn't answered in any of them — but it's entirely possible that it is and I missed it. In that case, I'll be grateful if someone points out where.)
Consider the following statement about sets and functions, which I'll call "axiom A":
A. For all well-ordered sets $(B, leq)$, there exist a set $X$ and a function $p: X to B$ with the following property:
for all $b in B$, the fibre $p^-1(b)$ is an infinite set of smallest cardinality greater than that of $p^-1(b')$ for each $b' < b$.
In the traditional notation of set theory, if $(B, leq)$ is an ordinal $beta$, then $p^-1(alpha) cong aleph_alpha$ for each $alpha in beta$. So, $X$ is the disjoint union $coprod_alpha in beta aleph_alpha$ and $p: X to beta$ is the obvious projection.
My question is about ETCS (Lawvere's Elementary Theory of the Category of Sets) together with axiom A. In what follows, I'm going to take ETCS as the background theory. Thus, when I say "this is weaker than that", I mean weaker in the presence of ETCS.
On the one hand, A isn't a theorem of ETCS (unless, of course, ETCS is inconsistent). That's because ETCS+A proves the existence of $aleph_omega$ but ETCS alone doesn't.
On the other, if I'm not mistaken, A is weaker than replacement. That's because ETCS+replacement is bi-interpretable with ZFC, and unless I'm misremembering, the fact that ETCS+A is a finite list of axioms (not involving axiom schemes) somehow implies that it can't be as strong as ZFC.
So, it seems that axiom A is a weaker form of replacement. My question:
To what fragment of replacement is axiom A equivalent (in the presence of the axioms of ETCS)?
That question is a little vague, so let me focus it more:
What's the simplest statement you can think of that's true in ETCS+replacement (or equivalently ZFC) but not provable in ETCS+A?
I don't mind whether the statement is purely set-theoretic or from another part of mathematics.
ct.category-theory set-theory lo.logic
$endgroup$
(There have been many questions on MathOverflow about the axiom scheme of replacement, including a few with a similar flavour to mine. Some have very informative answers and link to excellent papers and blog posts. I've spent a while reading the older questions etc., and as far as I know, my question isn't answered in any of them — but it's entirely possible that it is and I missed it. In that case, I'll be grateful if someone points out where.)
Consider the following statement about sets and functions, which I'll call "axiom A":
A. For all well-ordered sets $(B, leq)$, there exist a set $X$ and a function $p: X to B$ with the following property:
for all $b in B$, the fibre $p^-1(b)$ is an infinite set of smallest cardinality greater than that of $p^-1(b')$ for each $b' < b$.
In the traditional notation of set theory, if $(B, leq)$ is an ordinal $beta$, then $p^-1(alpha) cong aleph_alpha$ for each $alpha in beta$. So, $X$ is the disjoint union $coprod_alpha in beta aleph_alpha$ and $p: X to beta$ is the obvious projection.
My question is about ETCS (Lawvere's Elementary Theory of the Category of Sets) together with axiom A. In what follows, I'm going to take ETCS as the background theory. Thus, when I say "this is weaker than that", I mean weaker in the presence of ETCS.
On the one hand, A isn't a theorem of ETCS (unless, of course, ETCS is inconsistent). That's because ETCS+A proves the existence of $aleph_omega$ but ETCS alone doesn't.
On the other, if I'm not mistaken, A is weaker than replacement. That's because ETCS+replacement is bi-interpretable with ZFC, and unless I'm misremembering, the fact that ETCS+A is a finite list of axioms (not involving axiom schemes) somehow implies that it can't be as strong as ZFC.
So, it seems that axiom A is a weaker form of replacement. My question:
To what fragment of replacement is axiom A equivalent (in the presence of the axioms of ETCS)?
That question is a little vague, so let me focus it more:
What's the simplest statement you can think of that's true in ETCS+replacement (or equivalently ZFC) but not provable in ETCS+A?
I don't mind whether the statement is purely set-theoretic or from another part of mathematics.
ct.category-theory set-theory lo.logic
ct.category-theory set-theory lo.logic
asked 4 hours ago
Tom LeinsterTom Leinster
19.5k475128
19.5k475128
2
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One easy way to see that this is weaker than Replacement is to take any $beth$-fixed point, $delta$, and look at $V_delta$ as a model of Zermelo set theory (which is stronger than ETCS) where $aleph_alpha$ exists for every ordinal $alpha$, and every well-ordered set is isomorphic to a von Neumann ordinal. So the question is, essentially, how much Replacement holds for the least such $delta$...
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
Also, note that Power set is quite essentially here. Otherwise $H(omega_1)$, the set of hereditarily countable sets, satisfies ZFC-Power set (including full Replacement), but all infinite sets are equipotent there.
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
@AsafKaragila yes, a topos has power objects, so we are ok there :-)
$endgroup$
– David Roberts
1 hour ago
add a comment |
2
$begingroup$
One easy way to see that this is weaker than Replacement is to take any $beth$-fixed point, $delta$, and look at $V_delta$ as a model of Zermelo set theory (which is stronger than ETCS) where $aleph_alpha$ exists for every ordinal $alpha$, and every well-ordered set is isomorphic to a von Neumann ordinal. So the question is, essentially, how much Replacement holds for the least such $delta$...
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
Also, note that Power set is quite essentially here. Otherwise $H(omega_1)$, the set of hereditarily countable sets, satisfies ZFC-Power set (including full Replacement), but all infinite sets are equipotent there.
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
@AsafKaragila yes, a topos has power objects, so we are ok there :-)
$endgroup$
– David Roberts
1 hour ago
2
2
$begingroup$
One easy way to see that this is weaker than Replacement is to take any $beth$-fixed point, $delta$, and look at $V_delta$ as a model of Zermelo set theory (which is stronger than ETCS) where $aleph_alpha$ exists for every ordinal $alpha$, and every well-ordered set is isomorphic to a von Neumann ordinal. So the question is, essentially, how much Replacement holds for the least such $delta$...
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
One easy way to see that this is weaker than Replacement is to take any $beth$-fixed point, $delta$, and look at $V_delta$ as a model of Zermelo set theory (which is stronger than ETCS) where $aleph_alpha$ exists for every ordinal $alpha$, and every well-ordered set is isomorphic to a von Neumann ordinal. So the question is, essentially, how much Replacement holds for the least such $delta$...
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
Also, note that Power set is quite essentially here. Otherwise $H(omega_1)$, the set of hereditarily countable sets, satisfies ZFC-Power set (including full Replacement), but all infinite sets are equipotent there.
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
Also, note that Power set is quite essentially here. Otherwise $H(omega_1)$, the set of hereditarily countable sets, satisfies ZFC-Power set (including full Replacement), but all infinite sets are equipotent there.
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
@AsafKaragila yes, a topos has power objects, so we are ok there :-)
$endgroup$
– David Roberts
1 hour ago
$begingroup$
@AsafKaragila yes, a topos has power objects, so we are ok there :-)
$endgroup$
– David Roberts
1 hour ago
add a comment |
1 Answer
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$begingroup$
Asaf points out that Axiom A is true in $V_delta$ if $delta$ is a $beth$ fixed point. Full replacement only holds if $delta$ is worldly. So, in $V_delta$ models of these, replacement implies a proper class of $beth$ fixed points (since all worldly cardinals are $beth$ fixed point-sized limits of $beth$ fixed points), but Axiom A is compatible with the statement that there are no $beth$ fixed points. In fact, ZFC does proves that there's a proper class of $beth$ fixed points, since for any ordinal $alpha$ the limit of the sequence $beta_0 = alpha; beta_n+1 = beth_beta_n$ is a $beth$ fixed point greater than $alpha$.
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$begingroup$
Asaf points out that Axiom A is true in $V_delta$ if $delta$ is a $beth$ fixed point. Full replacement only holds if $delta$ is worldly. So, in $V_delta$ models of these, replacement implies a proper class of $beth$ fixed points (since all worldly cardinals are $beth$ fixed point-sized limits of $beth$ fixed points), but Axiom A is compatible with the statement that there are no $beth$ fixed points. In fact, ZFC does proves that there's a proper class of $beth$ fixed points, since for any ordinal $alpha$ the limit of the sequence $beta_0 = alpha; beta_n+1 = beth_beta_n$ is a $beth$ fixed point greater than $alpha$.
$endgroup$
add a comment |
$begingroup$
Asaf points out that Axiom A is true in $V_delta$ if $delta$ is a $beth$ fixed point. Full replacement only holds if $delta$ is worldly. So, in $V_delta$ models of these, replacement implies a proper class of $beth$ fixed points (since all worldly cardinals are $beth$ fixed point-sized limits of $beth$ fixed points), but Axiom A is compatible with the statement that there are no $beth$ fixed points. In fact, ZFC does proves that there's a proper class of $beth$ fixed points, since for any ordinal $alpha$ the limit of the sequence $beta_0 = alpha; beta_n+1 = beth_beta_n$ is a $beth$ fixed point greater than $alpha$.
$endgroup$
add a comment |
$begingroup$
Asaf points out that Axiom A is true in $V_delta$ if $delta$ is a $beth$ fixed point. Full replacement only holds if $delta$ is worldly. So, in $V_delta$ models of these, replacement implies a proper class of $beth$ fixed points (since all worldly cardinals are $beth$ fixed point-sized limits of $beth$ fixed points), but Axiom A is compatible with the statement that there are no $beth$ fixed points. In fact, ZFC does proves that there's a proper class of $beth$ fixed points, since for any ordinal $alpha$ the limit of the sequence $beta_0 = alpha; beta_n+1 = beth_beta_n$ is a $beth$ fixed point greater than $alpha$.
$endgroup$
Asaf points out that Axiom A is true in $V_delta$ if $delta$ is a $beth$ fixed point. Full replacement only holds if $delta$ is worldly. So, in $V_delta$ models of these, replacement implies a proper class of $beth$ fixed points (since all worldly cardinals are $beth$ fixed point-sized limits of $beth$ fixed points), but Axiom A is compatible with the statement that there are no $beth$ fixed points. In fact, ZFC does proves that there's a proper class of $beth$ fixed points, since for any ordinal $alpha$ the limit of the sequence $beta_0 = alpha; beta_n+1 = beth_beta_n$ is a $beth$ fixed point greater than $alpha$.
answered 54 mins ago
B2CB2C
334
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$begingroup$
One easy way to see that this is weaker than Replacement is to take any $beth$-fixed point, $delta$, and look at $V_delta$ as a model of Zermelo set theory (which is stronger than ETCS) where $aleph_alpha$ exists for every ordinal $alpha$, and every well-ordered set is isomorphic to a von Neumann ordinal. So the question is, essentially, how much Replacement holds for the least such $delta$...
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
Also, note that Power set is quite essentially here. Otherwise $H(omega_1)$, the set of hereditarily countable sets, satisfies ZFC-Power set (including full Replacement), but all infinite sets are equipotent there.
$endgroup$
– Asaf Karagila
4 hours ago
$begingroup$
@AsafKaragila yes, a topos has power objects, so we are ok there :-)
$endgroup$
– David Roberts
1 hour ago